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Predicting The Response To Immunotherapy Using Artificial Intelligence

27 Aug 2018 | By Inserm (Newsroom) | Cancer | Health technologies

Photo by Ken Treloar on Unsplash

A study published in The Lancet Oncology establishes for the first time that artificial intelligence can process medical images to extract biological and clinical information. By designing an algorithm and developing it to analyse CT scan images, medical researchers at Gustave Roussy, CentraleSupélec, Inserm, Paris-Sud University and TheraPanacea (spin-off from CentraleSupélec specialising in artificial intelligence in oncology-radiotherapy and precision medicine) have created a so-called radiomic signature. This signature defines the level of lymphocyte infiltration of a tumour and provides a predictive score for the efficacy of immunotherapy in the patient.     

In the future, physicians might thus be able to use imaging to identify biological phenomena in a tumour located in any part of the body without having to perform a biopsy.  

Up to now, no marker can accurately identify those patients who will respond to anti-PD-1/PD-L1 immunotherapy in a situation where only 15 to 30% of patients do respond to such treatment. It is known that the richer the tumour environment is immunologically (presence of lymphocytes) the greater the chance that immunotherapy will be effective, so the researchers have tried to characterise this environment using imaging and correlate this with the patients’ clinical response. Such is the objective of the radiomic signature designed and validated in the study published in The Lancet Oncology.

In this retrospective study, the radiomic signature was captured, developed and validated in 500 patients with solid tumours (all sites) from four independent cohorts. It was validated genomically, histologically and clinically, making it particularly robust. 

Using an approach based on machine learning, the team first taught the algorithm to use relevant information extracted from CT scans of patients participating in the MOSCATO study[1], which also held tumor genome data. Thus, based solely on images, the algorithm learned to predict what the genome might have revealed about the tumour immune infiltrate, in particular with respect to the presence of cytotoxic T-lymphocytes (CD8) in the tumour, and it established a radiomic signature.   

This signature was tested and validated in other cohorts including that of TCGA (The Cancer Genome Atlas) thus showing that imaging could predict a biological phenomenon, providing an estimation of the degree of immune infiltration of a tumour.  

Then, to test the applicability of this signature in a real situation and correlate it to the efficacy of immunotherapy, it was evaluated using CT scans performed before the start of treatment in patients participating in 5 phase I trials of anti-PD-1/PD-L1 immunotherapy. It was found that the patients in whom immunotherapy was effective at 3 and 6 months had higher radiomic scores as did those with better overall survival.     

The next clinical study will assess the signature both retrospectively and prospectively, will use larger numbers of patients and will stratify them according to cancer type in order to refine the signature.        

This will also employ more sophisticated automatic learning and artificial intelligence algorithms to predict patient response to immunotherapy. To that end, the researchers are intending to integrate data from imaging, molecular biology and tissue analysis. This is the objective of the collaboration between Gustave Roussy, Inserm, Université Paris-Sud, CentraleSupélec and TheraPanacea to identify those patients who are the most likely to respond to treatment, thus improving the efficacy/cost ratio of the treatment.

[1] Results of the MOSCATO study published in Cancer Discovery :

// About radiomics

In radiomics, it is considered that imaging (CT, MRI, ultrasound, etc.) not only reveals the organisation and architecture of tissues but also their molecular or cellular composition. The technique involves the use of algorithms to analyse a medical image objectively in order to extract from it information which is invisible to the naked eye, such as the texture of a tumour, its micro-environment, its heterogeneity, etc. For the patient this represents a non-invasive approach that can be repeated over the course of the disease to follow its progress. 

Researcher Contact
Eric Deutsch Centre de lutte contre le cancer Unité 1030 Radiothérapie moléculaire Téléphone : 01 42 11 42 11 Adresse électronique : rf.yssuorevatsug@hcstued.cire
Press Contact
Service de presse de l'Inserm rf.mresni@esserp Service de presse Gustave Roussy Claire Parisel Tél. 01 42 11 50 59 – 06 17 66 00 26 rf.yssuorevatsug@lesirap.erialc Service de presse de CentraleSupélec Laurence Wendling Tel. 01 75 31 61 15 rf.celepuselartnec@gnildnew.ecneruaL Service de presse de TheraPanacea Catherine Martineau-Huynh Tel. ue.aecanapareht@hnyuh.c Service de presse de Université Paris-Sud Cécile Pérol Tél. 01 69 15 41 99 - 06 58 24 68 44 rf.dusp-u@lorep.elicec
Radiomics to assess tumor infiltrating CD8 T-cells and response to anti-PD-1/PD-L1 immunotherapy in cancer patients: an imaging biomarker multi-cohort study Lancet Oncology, DOI : 10.1016/S1470-2045(18)30413-3 Roger Sun (MD, MSc)1,2,3*, Elaine Johanna Limkin (MD)1,2,3*, Maria Vakalopoulou (PhD)3,4,7 Laurent Dercle (MD, MSc)5, Stéphane Champiat (MD, PhD)6, Shan Rong Han (MD)7, Loïc 8 Verlingue (MD, MSc)6, David Brandao (MSc)8, Andrea Lancia (MD)1,3,9, Samy Ammari 9 (MD, MSc)10, Antoine Hollebecque (MD)6, Jean-Yves Scoazec (Prof, MD, PhD)11,12, 10 Aurélien Marabelle (MD, PhD)6, Christophe Massard (MD, PhD)6, Jean-Charles Soria (Prof, 11 MD, PhD)6,12, Charlotte Robert (PhD)1,3,12,13, Nikos Paragios (Prof, PhD) 3,4,14, Eric Deutsch 12 (Prof, MD, PhD)1,2,3,6,12†, Charles Ferté (MD, PhD) 1,3,6† 1 INSERM U1030, Radiomics team, Gustave Roussy Cancer Campus, 94800 Villejuif, France 2 Department of Radiation Oncology, Gustave Roussy Cancer Campus, 94800 Villejuif, 18 France 3 Gustave Roussy - CentraleSupelec - Therapanacea Center of Artificial Intelligence in Radiation Therapy & Oncology, Gustave Roussy Cancer Campus, 94800 Villejuif, France 4 Center for Visual Computing, CentraleSupelec, INRIA, Paris-Saclay University, 91190 Gif-sur-Yvette, France 5 Department of Nuclear Medicine and Endocrine Oncology, Gustave Roussy Cancer Campus, INSERM U1015, Paris Saclay university, 94800 Villejuif, France, 6 Drug development Department, Gustave Roussy Cancer Campus, 94800 Villejuif, France 7 Pathology department, Hôpital Nord Franche-Comté, 100 route de Moval – CS 10499 Trevenans, 90015 Belfort, France 8 INSERM U1170, Gustave Roussy Cancer Campus, 94800 Villejuif, France 9 Department of Diagnostic Imaging, Molecular Imaging, Interventional Radiology And Radiotherapy, Tor Vergata General Hospital, 00133 Rome, Italy 10 Department of Radiology, Gustave Roussy Cancer Campus, 94800 Villejuif, France 11 Department of Pathology, Gustave Roussy Cancer Campus, 94800 Villejuif, France 12  Paris-Sud University, Faculté de médecine du Kremlin-Bicêtre,  94270 Kremlin-Bicêtre, France 13 Department of Medical Physics, Gustave Roussy Cancer Campus, 94800 Villejuif, France 14 TheraPanacea, 75014, Paris, France